US5640698A - Radio frequency signal reception using frequency shifting by discrete-time sub-sampling down-conversion - Google Patents
Radio frequency signal reception using frequency shifting by discrete-time sub-sampling down-conversion Download PDFInfo
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- US5640698A US5640698A US08/468,280 US46828095A US5640698A US 5640698 A US5640698 A US 5640698A US 46828095 A US46828095 A US 46828095A US 5640698 A US5640698 A US 5640698A
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04B—TRANSMISSION
- H04B1/00—Details of transmission systems, not covered by a single one of groups H04B3/00 - H04B13/00; Details of transmission systems not characterised by the medium used for transmission
- H04B1/0003—Software-defined radio [SDR] systems, i.e. systems wherein components typically implemented in hardware, e.g. filters or modulators/demodulators, are implented using software, e.g. by involving an AD or DA conversion stage such that at least part of the signal processing is performed in the digital domain
- H04B1/0007—Software-defined radio [SDR] systems, i.e. systems wherein components typically implemented in hardware, e.g. filters or modulators/demodulators, are implented using software, e.g. by involving an AD or DA conversion stage such that at least part of the signal processing is performed in the digital domain wherein the AD/DA conversion occurs at radiofrequency or intermediate frequency stage
- H04B1/0025—Software-defined radio [SDR] systems, i.e. systems wherein components typically implemented in hardware, e.g. filters or modulators/demodulators, are implented using software, e.g. by involving an AD or DA conversion stage such that at least part of the signal processing is performed in the digital domain wherein the AD/DA conversion occurs at radiofrequency or intermediate frequency stage using a sampling rate lower than twice the highest frequency component of the sampled signal
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- H—ELECTRICITY
- H03—ELECTRONIC CIRCUITRY
- H03D—DEMODULATION OR TRANSFERENCE OF MODULATION FROM ONE CARRIER TO ANOTHER
- H03D7/00—Transference of modulation from one carrier to another, e.g. frequency-changing
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04B—TRANSMISSION
- H04B1/00—Details of transmission systems, not covered by a single one of groups H04B3/00 - H04B13/00; Details of transmission systems not characterised by the medium used for transmission
- H04B1/0003—Software-defined radio [SDR] systems, i.e. systems wherein components typically implemented in hardware, e.g. filters or modulators/demodulators, are implented using software, e.g. by involving an AD or DA conversion stage such that at least part of the signal processing is performed in the digital domain
-
- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04B—TRANSMISSION
- H04B1/00—Details of transmission systems, not covered by a single one of groups H04B3/00 - H04B13/00; Details of transmission systems not characterised by the medium used for transmission
- H04B1/06—Receivers
- H04B1/16—Circuits
- H04B1/26—Circuits for superheterodyne receivers
Definitions
- the present invention relates to radio receivers and methods for the reception of RF (radio frequency) communications signals.
- RF radio frequency
- the present invention relates to radio receivers using high-speed discrete-time electronic circuits and methods for RF signal reception using sub-sampling for frequency down-conversion.
- the vast majority of RF communications receivers are of the traditional superheterodyne type.
- This type of receiver uses one or more IF (intermediate frequency) stages for filtering and amplifying signals at a fixed frequency within an IF chain.
- This radio architecture has the advantage that fixed filters may be used in the LO (local oscillator) chain.
- FIG. 1 A block diagram of a typical superheterodyne radio receiver is shown in FIG. 1.
- An RF signal arriving at an antenna 11 passes through a bandpass RF filter 13, an LNA (low noise amplifier) 15 and into an image filter 17 which produces a band-limited RF signal.
- This band-limited RF signal then enters a first mixer 19 which translates the RF signal down to an intermediate frequency by mixing it with the signal produced by a first LO (local oscillator) 21.
- the undesired mixer products in the IF signal are rejected by an IF filter 23.
- the filtered IF signal then enters a second mixer 25 which translates it down to yet another intermediate frequency by mixing it with the signal produced by a second LO 27.
- the signal finally passes through an IF amplifier 29 and an IF filter 31, resulting in a channelized IF signal, i.e., a signal containing a particular channel isolated from the other channels present within the original band-limited RF signal.
- An analog demodulator 33 demodulates the channelized IF signal into a baseband information signal. Tuning into a particular channel within the band-limited RF signal is accomplished by varying the LO frequency of LO 21.
- the superheterodyne design requires high-quality, narrowband IF bandpass filters operating at high frequencies, and these components can not be built on-chip with present technology. Instead, off-chip components such as SAW (surface acoustic wave) filters or tuned circuits requiring resonating components such as inductors or cavities must be used. These external filtering components impose a lower limit to the size, materials cost, assembly cost, and power consumption of receivers built using the superheterodyne design. Moreover, the necessity for mixer and local oscillator circuits operating at high frequencies contributes greatly to the power consumption and general complexity of the superheterodyne receiver. In particular, high-frequency analog mixers often require a large amount of power to maintain linear operation. Although many variations of the superheterodyne design exist, they all share the limitations of the particular design just described.
- a digital IF receiver design as shown in FIG. 2, can be integrated further than the superheterodyne design and therefore requires fewer external components.
- an antenna 35 couples an RF signal through an RF filter 37 into an LNA 39 and then through an image filter 41.
- the band-limited RF signal mixes in a mixer 43 with a LO signal from a LO 45 to produce an IF signal.
- the IF signal then is amplified in an IF amplifier 47 before being channelized in an IF filter 49.
- An ADC (analog-to-digital converter) 51 operating at a conversion rate determined by a clock circuit 53, digitizes the channelized IF signal into a digital IF signal.
- This digital IF signal is filtered and demodulated by a digital demodulator 55 and is passed on to the remainder of the communications system as a digital baseband information signal. Tuning is accomplished by varying the frequency of LO 45. Multiple techniques for performing the digital filtering and demodulation have been developed for this receiver design such as those described in U.S. Pat. Nos. 4,888,557 and 4,902,979.
- the digital IF design can cost less to manufacture and assemble because it has fewer off-chip components. Nevertheless, the digital IF design still requires several off-chip components, namely, external IF filters, a high-frequency mixer, and a high-frequency LO.
- U.S. Pat. No. 5,339,459 describes a technique that eliminates the necessity for external high-frequency mixer and LO circuits by using a sample-and-hold circuit. By operating at a sampling rate lower than the band-limited RF signal, i.e. by sub-sampling, the sample-and-hold circuit acts as a mixer to translate the RF signal into an IF signal. Although this technique allows further integration and lower power operation, it still requires the use of off-chip components for the high-quality, narrowband IF bandpass filters needed for channelization.
- the digital IF design has other disadvantages as well.
- the ADC In order to faithfully digitize the analog signal, the ADC is required to operate at a conversion rate of at least twice the intermediate frequency. Such a high-frequency ADC consumes a large amount of power to maintain the required linearity and dynamic range. This becomes even more problematic for receiver designs in which the A/D conversion is performed at the front end of the receiver, e.g., as in U.S. Pat. No. 4,893,316.
- a third receiver design is the direct-conversion, or zero-IF, receiver shown in FIG. 3.
- An antenna 57 couples an RF signal through a first bandpass RF filter 59 into an LNA 61.
- the signal then proceeds through a second RF filter 63, yielding a band-limited RF signal, which then enters a mixer 65 and mixes with an LO frequency produced by an LO 67.
- the direct-conversion receiver design is essentially the same as the two previous receiver designs.
- the LO frequency is set to the carrier frequency of the RF channel of interest.
- the resulting mixer product is a zero-frequency IF signal-a modulated signal at baseband frequency.
- This signal couples into a lowpass analog filter 69 before proceeding into an analog demodulator 71 to yield the demodulated analog baseband information signal for use by the remainder of the communications system.
- an analog-to-digital converter can be inserted after mixer 65 and the filtering and demodulation can be done digitally, producing a digital baseband information signal for use by the remainder of the communications system. In either case, tuning is accomplished by varying the frequency of LO 67, thereby converting different RF channels to zero-frequency IF signals.
- the direct-conversion receiver design produces a zero-frequency IF signal
- its filter requirements are greatly simplified--no external IF filter components are needed since the zero-IF signal is an audio frequency signal that can be filtered by a low-quality lowpass filter.
- This allows the receiver to be integrated in a standard silicon process from mixer 65 onwards, making the direct-conversion receiver design potentially attractive for portable applications.
- the direct-conversion design has several problems, some of which are quite serious.
- the RF and image filters required in the direct-conversion design must be high-quality narrowband filters that must remain off-chip.
- this design requires the use of high-frequency mixer and LO circuits that require large amounts of power.
- radiated power from LO 67 can couple into antenna 57, producing a DC offset at the output of mixer 65. This DC offset can be much greater than the desired zero-IF signal, making signal reception difficult. Radiated power from LO 67 can also affect other nearby direct-conversion receivers tuned to the same radio frequency.
- two mixers and two LOs are required to produce both an in-phase and a quadrature baseband signal. Not only does this increase the power required by the receiver, but also the phase between the two LO signals must be precisely maintained at 90 degrees to prevent demodulation distortion. This can be difficult to accomplish with variations in temperature and other operational parameters.
- each one has significant disadvantages including one or more of the following: the necessity for several external circuit components, the consumption of large amounts of power, poor signal reception, interference with other receivers, distortion, and limited dynamic range.
- the present invention achieves the above objects and advantages by providing a new method for RF communications signal reception and a new receiver design that incorporates this method.
- This method includes filtering an RF signal containing a channel allocation band of bandwidth B to yield a band-limited RF signal of bandwidth W.
- An RF channel of carrier frequency f c is included within this channel allocation band.
- the method further includes a sample-and-hold means to sub-sample the band-limited RF signal at a sampling rate f s ⁇ f c in order to obtain an image signal of the RF channel.
- the method includes a discrete-time down-converting means to successively down-convert, filter, and amplify the image signal of the RF channel to a low-frequency signal of frequency f k .
- the down-converting method of the invention employs discrete-time signal processing techniques that do not require digital conversion and processing of the signal.
- FIG. 1 is a block diagram of a superheterodyne receiver considered as prior art.
- FIG. 2 is a block diagram of a digital IF receiver considered as prior art.
- FIG. 3 is a block diagram of a direct-conversion receiver considered as prior art.
- FIG. 4 is a block diagram of a receiver constructed with the principles of the invention.
- FIG. 5 is a block diagram of a discrete-time signal processing block, which is a key component of a receiver constructed according to the invention.
- FIG. 6 is a graph showing a typical arrangement of RF channels within a channel allocation band used for common radio communications.
- FIG. 7 is a graph showing the band-limited RF signal after passing through the noise filter of FIG. 4 according to the invention.
- FIG. 8 is a graph showing the spectrum of image signals after the band-limited RF signal is sub-sampled according to the invention.
- FIGS. 9a and 9b are graphs illustrating the necessary relationships between f s , f i , B, and W to permit sub-sampling without destructive aliasing.
- FIG. 10 pictorially illustrates the aliasing of spectral components due to 2:1 down-sampling.
- FIG. 11 is a graph showing the normalized frequency response of the discrete-time anti-aliasing filters used in the preferred embodiment.
- FIG. 4 is a block diagram of an RF communications receiver constructed in accordance with the principles of the present invention. It includes an antenna 73 for coupling an RF signal into the input of an analog bandpass RF filter 75.
- the output of analog bandpass RF filter 75 connects to the input of an LNA 77 whose output couples to the input of an analog noise filter 79.
- the output of analog RF noise filter 79 connects to the input of a sample-and-hold circuit 81, which is built using switched-capacitor circuit techniques.
- sample-and-hold circuit 81 In addition to its signal input which connects to the output of RF noise filter 79, sample-and-hold circuit 81 has a clock input and a discrete-time signal output. Its discrete-time signal output connects at a node 82 to the input of a discrete-time signal processing block 85.
- Discrete-time signal processing block 85 is a key component of the preferred embodiment of the invention and is described in greater detail below in connection with FIG. 5.
- the output of discrete-time signal processing block 85 couples through node 86 to the input of an ADC 87 whose output connects to the input of a digital filter 91.
- the output of digital filter 91 couples to the input of a digital demodulation circuit 93 whose digital baseband output feeds into the remainder of the communications system.
- Clock circuit 83 has j+1 output lines which carry j+1 clock signals.
- One of these output lines from clock circuit 83 connects to sample-and-hold circuit 81 while another of these output lines from clock circuit 83 connects to ADC 87, digital filter 91, and digital demodulation circuit 93.
- Discrete-time signal processing block 85 also connects to clock circuit 83.
- the connection between these two circuits is a multiple-line connection that couples through node 84 and is composed of all j+1 clock signal lines. The relationships among the clock signals delivered from clock circuit 83 to these five circuit blocks are discussed later in this description.
- FIG. 5 illustrates the details of discrete-time signal processing block 85.
- This block is composed of j serially cascaded down-sampling stages 99.1 to 99.j.
- the input to down-sampling stage 99.1 serves as the input to discrete-time signal processing block 85 as a whole and connects through node 82 to the output of sample-and-hold circuit 81 of FIG. 4.
- the output of down-sampling stage 99.j serves as the output to discrete-time signal processing block 85 as a whole and connects through node 86 to the input of ADC 87 of FIG. 4.
- Each down-sampling stage connects to two clock signal lines. Except for the first and the last clock signal line in discrete-time signal processing block 85, each of the clock signal lines connect to two adjacent down-sampling stages.
- the first clock signal line that connects to discrete-time signal processing block 85 also connects to sample-and-hold circuit 81, and similarly, the last clock signal line that connects to discrete-time signal processing block 85 also connects to ADC 87, digital filter 91, and digital demodulation circuit 93. Accordingly, j+1 clock signal lines connect from the down-sampling stages through node 84 to clock circuit 83 of FIG. 4.
- Down-sampling stage 99.1 is composed of two circuits, a discrete-time anti-aliasing filter 95.1 and a N:1 discrete-time sampling down-converter 97.1. In the preferred embodiment, these two circuits are built using switched-capacitor circuit techniques.
- the output of discrete-time anti-aliasing filter 95.1 couples to the input of N:1 discrete-time sampling down-converter 97.1.
- Discrete-time anti-aliasing filter 95.1 and N:1 discrete-time sampling down-converter 97.1 each connect to a separate clock signal line from dock circuit 83. Note that the clock signal line that connects to the N:1 discrete-time sampling down-converter 97.1 also connects to discrete-time anti-aliasing filter 95.2.
- the other down-sampling stages 99.2 to 99.j have similar connections.
- FIG. 6 illustrates the characteristics of the RF communication signal of interest for the preferred embodiment.
- the following description illustrates the reception (down-conversion, filtering, and amplification) of a single analog voice channel 101a chosen from a set of analog voice channels 101 contained in a channel allocation band of bandwidth B.
- B 10 MHz
- each channel in the band has a 10 kHz information bandwidth and is separated from adjacent channels by 30 kHz.
- an antenna 73 couples RF signal energy into the input of an analog bandpass RF filter 75.
- Analog bandpass RF filter 75 is used to selectively pass a channel allocation band of bandwidth B while attenuating RF energy at frequencies outside this band, thereby producing a band-limited RF signal which includes a specific channel having carrier frequency f c .
- the band-limited RF signal then passes from the output of analog bandpass RF filter 75 to the input of LNA 77 which amplifies the signal while contributing minimal noise.
- the amplified RF signal from the output of LNA 77 is then coupled to RF noise filter 79.
- This RF noise filter 79 has a response similar to that of analog bandpass RF filter 75. It passes a bandwidth B of signal frequencies in the channel allocation band while attenuating any RF energy that lies outside this bandwidth, such as energy that may have been produced or amplified by LNA 77.
- This noise filter improves the performance of the receiver by preventing excessive noise from folding into the channel of interest when down-conversion is performed further along in the receiver.
- filters 75 and 79 efficiently pass signals within the passband of bandwidth B they also pass non-negligible signals in a larger, anti-aliasing bandwidth W including the passband of interest. (See FIGS. 9A and 9B)
- This anti-aliasing bandwidth W arises from the combined roll-off of the two filter responses determined by their quality factors.
- analog bandpass RF filter 75 and noise filter 79 must be high-quality filters built using off-chip components.
- LNA 77 can be integrated along with the rest of the receiver.
- the passband gain and noise performance of the front-end components from antenna 73 through sample-and-hold circuit 81 determine the noise figure and sensitivity of the receiver.
- the band-limited RF signal couples into the input of sample-and-hold circuit 81 which also receives a clock signal of frequency f s from clock generator circuit 83.
- This clock signal determines the sampling rate of sample-and-hold circuit 81. Because the sampling rate f s is less than the RF carrier frequency f c , sub-sampling will occur.
- the original signal is shown in FIG. 7 and its replication is shown in FIG. 8.
- the sampling rate, f s must be set above a minimum rate to avoid destructive aliasing during the sub-sampling process. This minimum rate is determined by both the bandwidth B of the allocation band and the bandwidth W of the front-end RF filters. To avoid aliasing an image channel of frequency f i in the image signal band, the image channel must not overlap with the outer tail of the envelope of the adjacent image signal band which contains the corresponding image channel of frequency f s -f i . The lower bound on the difference between f s -f i and f i depends on the position of the channel within the band.
- FIGS. 9a and 9b show the overlap between adjacent image bands in the best case and in the worst case, respectively.
- sample-and-hold circuit 81 couples the discrete-time signal through node 82 into the input of discrete-time signal processing block 85.
- This discrete-time signal processing block simultaneously performs anti-alias filtering, channel-select filtering, amplification, and frequency down-conversion of the signal in j successive steps, ultimately selecting and isolating analog voice channel 101a from within the channel allocation band and translating it in frequency down to a low-frequency signal of frequency f k .
- the discrete-time signal upon coupling through node 82 into discrete-time signal processing block 85, the discrete-time signal enters down-sampling stage 99.1. Inside down-sampling stage 99.1, the discrete-time signal passes through anti-aliasing filter 95.1, which is driven by a clock signal coupled through node 83 to operate at a rate f s equal to that of sample and hold circuit 81 of FIG. 4. Anti-aliasing filter 95.1 removes from the discrete-time signal all frequencies that would otherwise alias onto the desired channel during down-sampling and amplifies the remaining desired frequencies.
- the frequency response of anti-aliasing filter 95.1 used in the preferred embodiment is shown in FIG. 11 where the frequency axis is normalized to half its 150 MHz clock rate.
- the filtered and amplified discrete-time signal then couples into an N:1 discrete-time sampling down-converter 97.1.
- the N:1 discrete-time sampling down-converter 97.1 is a sample-and-hold circuit with a sampling rate of f s /N, where N, the down-sampling ratio, is an integer greater than one.
- N The use of a higher value for the down-sampling ratio N would require the use of a more complex anti-aliasing filter with more than one notch in its frequency response for removing the additional interfering signals that could alias onto the desired channel during down-sampling.
- the higher the value of N the greater the number of normalized frequencies that would have to be notched out. Accordingly, as N increased, the order of the discrete-time anti-aliasing filters would also have to increase.
- a lower down-sampling ratio is preferable, especially for the down-sampling stages in the high-speed front end. This ensures that an integrated filter is realizable.
- each discrete-time anti-aliasing filter 95.i is driven by clock circuit 83 to operate at a clock rate equal to the sampling rate of the N:1 discrete-time sampling down-converter 97.i-1 that preceded it.
- each successive down-sampling stage 99 is driven by clock circuit 83 to operate at a clock or sampling rate N times lower than the previous down-sampling stage.
- N the number of the previous down-sampling stage.
- the discrete-time signal is successively down-converted in frequency.
- the desired channel is successively amplified and filtered in order to separate it from the other channels originally present in the band-limited RF signal.
- the ratio of signal frequency to sample rate is critical in the design of the anti-aliasing filters in the down-sampling stages.
- In order to perform anti-alias filtering in the discrete-time domain it is necessary to ensure that the desired channel and aliasing interfering signals are separated as much as possible in frequency. This allows the separation between the stop band and pass band to be sufficiently large so that a low-order filter can be feasibly designed. Additionally, since many down-sampling stages are used, it is necessary to ensure that the separation between the stop band and pass band remains reasonable after many stages.
- the bandwidth of the desired channel becomes a significant fraction of the sample rate, a low-order filter is no longer sufficient for anti-aliasing because to properly prevent aliasing, the stop band must be wider than the bandwidth of the desired channel. At this point, however, the signal is shifted sufficiently down in frequency to make digital processing practical.
- FIG. 10 A frequency map showing the effect of 2:1 down-sampling is shown in FIG. 10.
- the upper frequency axis shows the signal frequency location of discrete-time signals just before being sampled by a 2:1 discrete-time sampling down-converter.
- the signal frequencies are normalized to the sampling rate of the 2:1 discrete-time sampling down-converter.
- the lower frequency axis shows the frequency spectrum just after down-sampling, normalized to the sampling rate of the next 2:1 discrete-time sampling down-converter.
- the arrows indicate the mapping of normalized frequency as a result of down-sampling.
- the channel frequency there are two special locations for the channel frequency: a normalized frequency of 4/5 and a normalized frequency of 2/3.
- the component that aliases onto the channel is located at a frequency of 1/5.
- the signal moves to a frequency of 2/5, and the aliasing frequency for the next stage of down-sampling is located at 3/5.
- the desired channel moves back up to a normalized frequency of 4/5, and the cycle can be continued until the signal bandwidth reaches the range 3/10 to 1/2 (0.3 to 0.5).
- the aliasing frequency is located at a frequency of 1/3.
- the desired channel remains at a normalized frequency of 2/3 with respect to the sampling rate of the next down-sampling stage.
- the desired channel never changes location relative to the sampling frequency.
- This down-sampling can be continued until the channel bandwidth spans the range 1/2 to 5/6 (0.5 to 0.833) after which it becomes impossible to anti-alias filter in the discrete-time domain.
- the preferred embodiment uses this value of 2/3 for the location of the desired channel in normalized frequency.
- discrete-time signal processing block 85 samples and digitizes the signal at a conversion rate determined by clock circuit 83.
- this clock rate is the same as the sampling rate of the final 2:1 discrete-time sampling down-converter in discrete-time signal processing block 85, and is therefore low enough that ADC 87 does not consume large amounts of power.
- the digital representation of the desired channel is now passed into a digital filter 91 which performs the final channelization filtering of the desired channel before passing it on to a digital demodulator 93.
- Digital demodulator 93 demodulates the desired channel, extracting its information content onto a digital baseband output signal which it passes on to the rest of the communications system.
- the discrete-time anti-aliasing filters may be built using switched-current circuits or other techniques.
- the preferred embodiment performs the analog-to-digital conversion after the down-conversion, it is possible to perform the analog-to-digital conversion earlier in the receiver, such as just after sample-and-hold circuit 81.
- the successive down-conversion and filtering stages would then be implemented in the digital domain using digital filtering and decimation techniques. This option will become increasingly attractive as analog-to-digital conversion technology improves.
- the present invention is applicable to a large range of RF carrier frequencies, limited only by technology. Also, the present invention is applicable to many other channel allocation band configurations containing any number of channels, each of arbitrary bandwidth.
- the method may be used with any type of modulation including, for example, AM, FM, phase modulation, and digital forms of modulation such as quadrature amplitude modulation, phase shift keying, Gaussian minimum shift keying, and frequency shift keying.
Abstract
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Priority Applications (9)
Application Number | Priority Date | Filing Date | Title |
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US08/468,280 US5640698A (en) | 1995-06-06 | 1995-06-06 | Radio frequency signal reception using frequency shifting by discrete-time sub-sampling down-conversion |
ES96918262T ES2148767T3 (en) | 1995-06-06 | 1996-06-06 | RECEPTION OF RADIO FREQUENCY SIGNALS USING DISPLACEMENT OF FREQUENCIES BY DOWN-CONVERSION OF DISCRETE TIME SUB-SAMPLING. |
CA 2201753 CA2201753A1 (en) | 1995-06-06 | 1996-06-06 | Radio frequency signal reception using frequency shifting by discrete-time sub-sampling down-conversion |
AT96918262T ATE192000T1 (en) | 1995-06-06 | 1996-06-06 | HIGH FREQUENCY SIGNAL RECEPTION WITH FREQUENCY OFFSET THROUGH UNDER SAMPLING DOWNWARD CONVERSION |
PCT/US1996/009311 WO1996039750A1 (en) | 1995-06-06 | 1996-06-06 | Radio frequency signal reception using frequency shifting by discrete-time sub-sampling down-conversion |
AU60961/96A AU700076B2 (en) | 1995-06-06 | 1996-06-06 | Radio frequency signal reception using frequency shifting by discrete-time sub-sampling down-conversion |
DK96918262T DK0813770T3 (en) | 1995-06-06 | 1996-06-06 | Radio frequency signal reception using discrete-time downconversion by subsampling |
EP96918262A EP0813770B1 (en) | 1995-06-06 | 1996-06-06 | Radio frequency signal reception using frequency shifting by discrete-time sub-sampling down-conversion |
DE69607836T DE69607836T2 (en) | 1995-06-06 | 1996-06-06 | HIGH-FREQUENCY SIGNAL RECEPTION WITH FREQUENCY TRANSLATION BY SUBSCRIBING DOWNWARD CONVERSION |
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US08/468,280 US5640698A (en) | 1995-06-06 | 1995-06-06 | Radio frequency signal reception using frequency shifting by discrete-time sub-sampling down-conversion |
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US5640698A true US5640698A (en) | 1997-06-17 |
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US08/468,280 Expired - Lifetime US5640698A (en) | 1995-06-06 | 1995-06-06 | Radio frequency signal reception using frequency shifting by discrete-time sub-sampling down-conversion |
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US (1) | US5640698A (en) |
EP (1) | EP0813770B1 (en) |
AT (1) | ATE192000T1 (en) |
AU (1) | AU700076B2 (en) |
DE (1) | DE69607836T2 (en) |
DK (1) | DK0813770T3 (en) |
ES (1) | ES2148767T3 (en) |
WO (1) | WO1996039750A1 (en) |
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US6314309B1 (en) | 1998-09-22 | 2001-11-06 | Illinois Superconductor Corp. | Dual operation mode all temperature filter using superconducting resonators |
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Also Published As
Publication number | Publication date |
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EP0813770A4 (en) | 1997-12-29 |
DE69607836D1 (en) | 2000-05-25 |
WO1996039750A1 (en) | 1996-12-12 |
ES2148767T3 (en) | 2000-10-16 |
ATE192000T1 (en) | 2000-05-15 |
EP0813770B1 (en) | 2000-04-19 |
DE69607836T2 (en) | 2000-10-19 |
DK0813770T3 (en) | 2000-07-31 |
EP0813770A1 (en) | 1997-12-29 |
AU6096196A (en) | 1996-12-24 |
AU700076B2 (en) | 1998-12-17 |
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